Polynomial Lower Bounds for Arithmetic Circuits over Non-Commutative Rings

Abstract

We prove a lower bound of (n1.5) for the number of product gates in non-commutative arithmetic circuits for an explicit n-variate degree-n polynomial fn (over every field). We observe that this implies that over certain non-commutative rings R, any arithmetic circuit that computes the induced polynomial function fn: Rn → R, using the ring operations of addition and multiplication in R, requires at least (n1.5) multiplications. More generally, for any d≥ 2 and sufficiently large n, we obtain a lower bound of (dn) for n-variate degree-d polynomials, for both these models. Prior to our work, the only known lower bounds for the size of non-commutative circuits, or for the size of arithmetic circuits over any ring, were slightly super-linear in \n,d\: (n d) by Baur and Strassen, and (d n) by Nisan. (Nisan's bound was proved for non-commutative arithmetic circuits and implies a bound for arithmetic circuits over non-commutative rings by our observation).